Magnetically actuated reed switch assembly

ABSTRACT

A magnetically actuated reed switch assembly comprising contact means including first and second cooperating magnetically actuated reeds in spaced relation to each other, a permanent magnet rotatable about an axis transverse to the longitudinal axis of the reeds and positioned with respect to the contact means so that its force field at certain positions of its rotation operates to influence the contact means to open or close, the contact means and magnet being encased in a housing assembly including contact and magnet supporting chambers.

United States Patent Schlesinger, J r.

M lMarch 13, 1973 1 MAGNETICALLY ACTUATED REED SWITCH ASSEMBLY Bernard Edward Schlesinger, Jr., 9411 Macklin Court, Alexandria, Va. 22309 Filed: March 21, 1972 Appl. No.: 236,598

[76] Inventor:

[56] References Cited UNITED STATES PATENTS 2,485,024 10/1949 Valeetal. ..335/l54 2,834,846 5/1958 Eaves et al. ..335/l53 Primary Examiner-Roy N. Envall, Jr.

Att0rneyB. Edward Shlesinger, Jr. et al.

[57] ABSTRACT A magnetically actuated reed switch assembly comprising contact means including first and second cooperating magnetically actuated reeds in spaced relation to each other, a permanent magnet rotatable about an axis transverse to the longitudinal axis of the reeds and positioned with respect to the contact means so that its force field at certain positions of its rotation operates to influence the contact means to open or close, the contact means and magnet being encased in a housing assembly including contact and magnet supporting chambers.

29 Claims, 25 Drawing Figures 20 2 f as I4 PATENTEDMAR 1 3 I975 3,720,895

SHEET 10F 3 MAGNETICALLY ACTUATED REED SWITCH ASSEMBLY HISTORICAL BACKGROUND switches using a plurality of reed switches and a rotating magnet are old. Hammond U.S. Pat. No. 3,418,610, Palmer U.S. Pat. No. 3,328,732 and Posey U.S. Pat. No. 3,559,124 are examples of these types of devices.

One difficulty with the switch assemblies in the prior art is that they are susceptible to corrosive and otherwise damaging effects produced by contact with the ambient atmosphere. Another drawback is that they tend to be complex in structure and require relatively elaborate means to provide for their installation.

OBJECTS AND SUMMARY It is therefore an object of this invention to provide a magnetically actuated reed switch assembly in which both the reed contacts and the rotating magnet are encased in a housing.

It is a further object of this invention to provide a magnetically actuated reed switch assembly which is unitary in structure.

It is a further object of this invention to provide a magnetically actuated reed switch assembly which is capable of precisely timed actuation.

Still a further object of this invention is to provide a magnetically actuated reed switch assembly in which both the reed contacts and the rotating magnet are sealed from the ambient atmosphere thereby precluding the corrosion of mechanically cooperating components.

A further object of this invention is to provide a magnetically actuated reed switch assembly capable of low cost manufacture and ease of installation.

Yet another object of this invention is to provide a magnetically actuated reed switch assembly in which frictional effects are minimized.

Still a further object of this invention is to provide a magnetically actuated reed switch assembly which is capable of functioning as a rotary stepping switch.

A still further object of this invention is to provide a magnetically actuated reed switch assembly wherein the axis of rotation of the magnet is transverse to the axes of the reeds.

These and other objects of this invention will be apparent from the following description and claims.

In the accompanying drawing which illustrates by way of example various embodiments of this invention:

FIG. l is a plan view of the invention;

FIGS. 2 through 4, 5 and 6 are schematic views showing other embodiments of the invention with portions shown in dotted lines to illustrate various positions of several of the reeds;

FIG. 5A is a cross sectional view of an enlarged portion of the embodiment shown in FIG. 5;

FIG. 7 is a side elevational view in section of a further embodiment of the invention;

FIG. 7A is a top view of the embodiment shown in FIG. 7;

FIGS. 8, 9, l0, l1 and 12 are plan views of various other embodiments of the invention;

FIG. 9A is a sectional view of the embodiment shown in FIG. 9 taken along lines 9a-9a and viewed in the direction of the arrows;

FIG. I2a is a sectional view of the embodiment shown in FIG. 12 taken along line l2a-l2a and viewed in the direction of the arrows;

FIGS. 13 through 21 illustrate still further embodiments of the invention shown schematically.

FIGS. 1 THROUGH 6 In FIG. I, the capsule C forms the housing for reeds 2 and 4. The capsule C may be made of glass, plastic or any other material capable of sealing the reeds from the ambient atmosphere and not affecting a magnetic field. The reeds 2 and 4 are anchored at one end in the solid end portions '6 and 8 of capsule C. These end portions 6 and 8 may be glass seals in the case of a glass capsule or any other appropriate means for sealing off the interior of the capsule C such as a plug, cap, etc. The reeds 2 and 4 extend into the capsule C and have their respective ends 10 and 12 located in proximate relationship to each other and separated by a small distance. The reeds 2 and 4 are made of a material having good magnetic characteristics and electrical conductivity. Alternatively, the reeds 2 and 4 may be coated with a conductor such as copper, gold, etc. In the latter alternative the core of the coated reeds could be made of non-conductive ferromagnetic material. The reeds must also be capable of relative spatial displacement under the influence of a sufficiently strong magnetic field. To accomplish this several alternative constructions are possible; one or both reeds may be flexible, or the reeds may be rigid with at least one of them being anchored in a resilient mounting. Other possibilities for providing for the necessary freedom of movement will be obvious.

Encased in a second capsule D, is a permanent magnet M rigidly mounted on a shaft 14 and capsule of rotation on shaft 14 within capsule D. Shaft 14 passes through capsule D and is rotatably mounted at bearings 16 and 18. Shaft 14 and magnet M may be rotated by any appropriate means such as motor 20 and pulley and belt assembly 22.

The embodiments shown in FIGS. 2 through 6 are similar to that shown in FIG. 1 with the exception that the encapsulation means and rotation means are not shown. In the embodiment shown in FIG. 2, magnetically actuated reed 24 is rigid and non-polarized while reed 26 is flexible and polarized such that its north pole N is nearest reed 24. The reeds are normally in an open position. As magnet M is rotated to its dotted line position, reed 26 will be repelled by the north pole of magnet M and moved into contact with reed 24 as in the dotted line position. When the magnet is in the solid line position or any position except the dotted line position, the magnetic field at the north pole of reed 26 will not be sufficiently strong to cause reed 26 to be actuated into contact with reed 24. While the reeds 24 and 26 are shown positioned transversely to each other, it is obvious that other reed configurations are possible.

In FIG. 3, magnetically actuated flexible reeds 30 and 32 have acute bends 34 and 36, respectively, therein, near what would be their encapsulated ends. The reeds 30 and 32 are positioned such that contact feet 38 and 40 are parallel to each other and separated by a small distance. When rotatable magnet M is in the dotted line position, the magnetic field at bends 34 and 36 will be sufficiently strong to cause reeds 30 and 32 to move to their dotted line positions. When this occurs, the individual reeds 30 and 32 each follow arcuate paths about the point where they would be anchored in their sealingcapsules (not shown). Since the contact feet 38 and 40 also follow somewhat arcuate paths, they will come into contact with-each other in the manner shown in the dotted line reed positions. Since the reeds 30 and 32 are not polarized, a similar closing action will occur when the south pole S of magnet M is in the position closest to the reeds 30 and 32. When the magnet is in the solid line position, the magnet field at bends 34 and 36 is no longer sufficiently strong to attract the reeds 30 and 32 to their closed position.

It may be mentioned that, in all of the embodiments of this invention, the point of the rotation of the magnet where the reeds are actuated to open or close is dependent on various factors such as the ferromagnetic properties of the reeds, the strength of the permanent magnet, the spatial relationship. of the magnet and the reeds, and others. Variants of any of these factors will cause a difference in the actuation pattern of the reeds with respect to the rotation of the magnet.

The embodiment shown in FIG. 4 comprises of a pair of magnetically actuated flexible reeds 42 and 44 enclosed in a housing or capsule (not shown) and anchored at their respective ends 46 and 48. The reeds 42 and 44 have obtuse bends 50 and 52 therein near their encapsulated ends forming a pair of contact feet 54 and 56. The reeds 42 and 44 are positioned such that contact feet 54 and 56 are substantially parallel and separated by a small distance. Reed 42 is rigid and non-polarized whereas reed 44 is flexible and unpolarized. When permanent magnet M is in the dotted line position, the magnetic field contact 56 is sufficiently strong to move reed 44 into contact with reed 42. When magnet M is in the solid line position, the magnetic field at contact foot 56 is not sufficient to move it from its normal position and the reeds 42 and 44 remain open. In this manner, the reeds 42 and 44 will close once per 180 revolution of magnet M. A variation of this embodiment would have reed 44 rigid and unpolarized and reed 42 flexible and polarized. In this case, when the magnet M is in the dotted line position and the polarity of contact foot 54 is the same polarity as the proximate end of magnet M, reed 42 will be repelled by magnet M and moved into contact with reed 44. In this manner, the reeds will close once per rotation of magnet M. Other variations of this embodiment will be obvious.

The embodiment shown in FIG. 5 includes two magnetically actuated reeds 60 and 62 anchored at their respective ends 64 and 66. Reed 60 may be flexible and has a notch68 therein. Reed 62, which is flexible in the plane of the reeds 60 and 62 overlaps reed 60 at notch 68 and is partially disposed therein as shown in FIG. 5a. When magnet M is in the solid line position, reed 62 will be attracted toward magnet M and make contact with wall 70 of notch 68. When magnet M is in the dotted line position, the magnetic field at reed 62 is substantially less and it will return to its normally open position because of its inherent elasticity. In this manner, reeds 60 and 62 make contact once every 180 rotation of magnet M.

In FIG. 6, reeds 72 and 74, anchored at their respective ends 76 and 78 are each permanently polarized with the encapsulated ends having opposing polarities. Reed 74 is flexible and reed 72 may be either rigid or flexible. Accordingly, reeds 72 and 74 will come into contact with each other when the magnet M is in the dotted line position. In this position, the opposing magnetic field created by the south pole S of magnet M, will move reed 74 into contact with reed 72 if the field created by magnet M is sufficient to overcome the opposing fleld created by the south pole of reed 72.

Another variation of this embodiment would be to have reeds 72 and 74 polarized so that their encapsulated ends have opposite polarities and are normally closed. Reeds 72 and 74 would be opened once per revolution of the magnet M when the proximate pole of magnet M has a polarity identical to the encapsulated end of reed 74.

FIGS. 7 AND 8 An alternate embodiment of the invention would comprise a pair of magnetically actuated reeds 80 and 82 sealed in a elongated capsule C similar to the embodiment shown in FIG. 1. The permanent magnet M is likewise sealed in a capsule D and rigidly mounted on a shaft 84 which may be rotated by a knob 86 or any other means.

The second capsule D and magnet M are positioned so that the axis or rotation of magnet M passes through the point where reeds 80 and 82 make contact. With this configuration, the reeds 80 and 82 will close once per revolution of magnet M when the axis of polority of the magnet is parallel to the longitudinal axis of the reeds.

In FIG. 8, capsule D contains a permanent magnet M mounted for rotation about a shaft 88. Disposed radially from the axis of rotation of magnet M are two pairs of magnetically actuated reed contacts 90, 92 and 94, 96. They are each sealed in elongated capsules C and Cl which are fused or otherwise connected to capsule D. Since reeds 90, 92, 94 and 96 are unpolarized and flexible, each of the contact pairs 90, 92 and 94, 96 would be actuated to a closed position when the magnet M is in the position shown. In this manner, each of the contact pairs 90, 92 and 94, 96 will close simultaneously once per 180 revolution of magnet M.

FIGS. 9, 10 AND 11 FIG. 9 shows a further embodiment of the invention wherein the rotatable permanent magnet M is sealed in a capsule D and parallel magnetically actuated reeds 98 and 100 are sealed in a second capsule C. It is obvious that capsules C and D may be integral with each other, in open communication with each other, or sealed from each other without affecting the functioning of the system. As magnet M rotates about shaft 102 the reeds 98 and 100 will close once every revolution. This occurs when the magnet M is in the position shown.

In FIG. 10, capsules C and D, containing reed contact pairs 104 and 106 are disposed about the perimeter of capsule D. Permanent magnet M rotates within capsule D about shaft 108. As magnet M rotates and the north pole of the magnet M sequentially moves to positions W, X, Y and Z, the contacts pairs 104 and 106 are actuated according to the following table:

TABLE 1 Contact Pair O=pen, l=Closed 104 106 Position of North Pole FIG. 11 shows a capsule D containing a permanent magnet M rotatable about shaft 110 with reed capsules C, C1 and C2 disposed about its perimeter. Capsule C contains reed contact pair 112, capsule C1 contains reed contact pair 114 and capsule C2 contains reed contact pair 116. As magnet M rotates about shaft 110 and north pole N sequentially moves to positions W, X, Y and Z, the contact pairs 112, 114, and 116 are actuated according to the following table:

FIG. 12 shows an embodiment of the invention comprising a capsule or housing C which encases a number of cooperating, magnetically actuated reeds 118, 120, 122, 124 and a pair of rotating magnets 126 and 128. The magnets 126 and 128 are connected to armatures 130 and 132, respectively, which are rigidly connected to rotatable shaft 134. As shown in FIG. 12a, the rotating magnet assembly 126, 138, 132, 128 is positioned so as to rotate in a plane parallel to and above the plane defined by the reeds 1 18-124.

As one of the magnets 126 or 128 passes in proximity to flexible reed 120 or flexible reed 124, the magnetic attraction will urge that reed into contact with either of stationary reeds 118 or 122. It is obvious that the flexible reeds 120 and 124 will not be actuated to make contact with reeds 118 or 122 when either magnet 126 or 128 is positioned directly above the flexible reeds 120 or 124, but only when the magnets 126 and 128 are positioned on either side of them.

A more complete description of the switching pattern of this reed configuration will be discussed in the next section.

FIGS. 13 THROUGH 21 FIGS. 13 through 21 illustrate various reed configurations which may be used in the rotating magnet system shown in FIG. 12. in all instances, the magnetically actuated reeds are anchored at their outermost ends in a capsule or housing similar to the embodiments previously discussed. Their operation will be described for use in conjunction with a single rotating magnet capable of assuming the various positions shown in dotted lines, but are not limited to this specific combination.

FIG. 13 illustrates a reed configuration identical to that shown in FIG. 12. Reeds 136 and 138 are unpolarized and may be rigid or flexible. Flexible reeds 140 and 142 are also unpolarized and have their respective encapsulated ends disposed between contact feet 144 and 146 of reeds 136 and 138, respectively. Since reeds 140 and 142 are flexible and magnetically actuated, they will be moved into contact with either contact foot 144 or 146 when the rotatable magnet (not shown) is in an actuating position on either side of reeds 140 or 142. These actuating positions are A, H, E, and D. As the magnet (not shown) rotates and sequentially assumes positions A through H, the reeds 136, 132, 138 and 140 will be in the following positions relative to each other:

TABLE 3 Contact Pair 0=Open,l=Closed 136-142 142-138 138-140 140-136 Position of Magnet IQ'flmUO coco-coo ooo-oooc -ooooocc cooccoo- The reed configuration shown in FIG. 14 comprises flexible reeds 148, 150, 152 and 154 having transverse contact feet 156, 158, and 162 respectively. When a rotatable permanent magnet (not shown) is in a position adjacent to the long portion of each of the reeds 148, 150, 152 or 154, the encapsulated end of that reed will be moved from its normal position in a direction parallel to the plane of the reeds. If the magnet (not shown) is on the side of the reed which is adjacent to the contact foot of the subsequent reed (such as position A), the heel portion (e.g., 164) of the first mentioned reed (e.g., 154) will move into contact with the contact foot (e.g., 156) of the subsequent reed (e.g., 148). As the permanent magnet (not shown) is sequentially rotated to positions A through H, the reeds 148, 150, 152 and 154 will assume the following positions:

FIG. 15 illustrates a reed configuration comprising flexible reeds 166, 168, and 172 having bifurcated portions 174, 176, 178, respectively, at their encapsulated ends. When a permanent magnet (not TABLE Contact Pair 0=Open, l=Closed 166-168 168-170 170-172 172-166 Position of Magnet A l O 0 0 B 0 l 0 0 C l 0 O 0 D 0 l 0 0 E 0 0 l 0 F 0 0 0 l G 0 0 l 0 H 0 0 0 1 TABLE 6 Contact Pair 0=0pen. l=Closed 186-188 188-190 190-192 192-186 Position of Magnet A 0 0 0 0 B l I O O C 0 0 0 0 D 0 1 l 0 E 0 0 0 0 F 0 0 l l G 0 O 0 0 H l 0 0 1 FIG. 17 illustrates another variation on the reed configurations shown in FIGS. and 16. It includes flexible reeds 202, 204, 206 and 208 having bifurcated portions 210, 212, 214 and 216, respectively, at their encapsulated ends. Reeds actuation is accomplished in the same manner as in the embodiments shown in FIGS. 15 and 16. As the magnet (not shown) sequentially assumes positions A through 11, the reeds will be actuated in the following manner:

TABLE 7 Contact Pair 0=0pen,l=Closed 202-204 204-206 206-208 208-202 Position of Magnet A 0 O l B l l 0 0 C 0 0 O 0 D 0 1 o 0 E o 0 1 o F 0 o o o o o o 1 1 1-1 1 o o 0 FIG. 18 shows a reed configuration comprising flexible reeds 218, 220 and 222. Reed 218 has a bifurcated portion 224 at its encapsulated ends and reeds 220 and 222 have transverse contact feet 226 and 228, respectively, in a manner similar to the embodiments shown in FIGS. 15, 16 and 17, the reeds 218, 220 and 222 assume the following positions as the magnet (not shown) rotates through positions A through F:

TABLE 8 Contact Pair 0=Open, l=Closed 218-220 218-222 Position of Magnet coo-o- -o -ooo The reed configuration illustrated in FIG. 19 comprises reeds 230 and 232, which may be flexible or rigid, having contact feet 234 and 236, respectively, a flexible reed 238 having a bifurcated portion 240, and a flexible reed 242. Reed 238 will move into contact with either contact foot 234 or 236 when a permanent magnet (not shown) is in positions D or E, respectively. Furcations 244 and 246 are spaced from each other a distance such that they will make contact with reed 242 also when the magnet (not shown) is in position D and E. When the magnet is in positions A through H, reed 242 will be actuated into contact with furcations 244 and 246, respectively. As the permanent magnet (not shown) assumes positions A through H, the reeds will be actuated in the following manner:

TABLE 9 Contact Pair 0=Open, l=Closed 242-238 238-230 238-232 Position of Magnet moo--00- ocoo-ooo coca-coco TABLE 10 Contact Pair 0=Open, l=Closed 248-250 250-252 252-248 Position of Magnet A l 0 B 0 0 0 C 0 l O D 0 0 0 E 0 0 1 F 0 O 0 The reed configuration shown in FIG. 21 comprises flexible reeds 260, 262, 264 and 266 having bifurcated portions 270, 272, -274 and 276, respectively, at their encapsulated ends. The primary difference between this embodiment and that shown in FIG. 16 is that whereas reeds 286 and 190 (FIG. 16) could not be axially aligned due to the V-shaped bifurcations, reeds 260 and 264 (FIG. 21) may be axially aligned due to the irregularly shaped bifurcated portions 270, 272, 274 and 276. As the magnet (not shown) is rotated through positions A through H, the reeds will assume the following positions:

TABLE 1 1 Contact Pair 0=0pen, l=Closed 260-262 262264 264-266 266-260 Position of Magnet While specific reed configurations have been illustrated in FIGS. 13 through 21, it is obvious that any number of reeds could be positioned in a manner similar to those described above without departing from the scope of this invention.

While the invention has been described in connection with various embodiments thereof, it will be understood that it is capable of further modification, and that this application is intended to cover any variations, uses, or adaptations of the invention following, in general, the principles of the invention and including such departures from the present disclosure that come within known or customary practice in the art to which this invention pertains, and as may be applied to the essential features hereinbefore set forth and fall within the scope of the invention or the limits of the appended claims.

What I claim is:

1. A magnetically actuated reed switch assembly comprising:

a. contact means including first and second cooperating magnetically actuated reeds in spaced relation to each other,

b. a portion of said reeds being sealed in capsule means forming a substantially V-shaped bent configuration, said contacts cooperating with each other for making electrical contact at the apex of said V and c. magnetic means exerting a variable force field at the apex of said V,

d. said magnetic means being sealed in said capsule means,

c. said capsule means being gas impermeable.

2. A magnetically actuated reed switch assembly as in claim 1 and wherein:

a. said magnetic means includes a rotatable magnet.

3. A magnetically actuated reed switch assembly as in claim 2 and including:

a. means for rotating said magnet.

4. A magnetically actuated reed switch assembly as in claim 3 and wherein:

a. said rotating means includes a motor.

5. A magnetically actuated reed switch assembly as in claim 3 and wherein:

a. said rotating means are manual.

6. A magnetically actuated reed switch assembly as in claim 1 and wherein:

a. said first reed is rigid and said second reed is flexible and permanently polarized.

7. A magnetically actuated reed switch assembly as in claim 6 and wherein:

a. said reeds are normally open and b. said second reed is polarized 0. whereby said second reed will move into contact with said first reed once per revolution of said magnet when the opposing field of said magnet is sufficient to overcome the inherent resiliency of said second reed.

8. A magnetically actuated reed switch assembly as in claim 7 and wherein:

a. said reeds are transverse to each other.

9. A magnetically actuated reed switch assembly as in claim 6 and wherein:

a. said first reed is permanently polarized.

10. A magnetically actuated reed switch assembly as in claim 9 and wherein:

a. said reeds are polarized in a direction such that their respective magnet fields oppose each other and are normally open.

11. A magnetically actuated reed switch assembly as in claim 10 and wherein:

a. said reeds are transverse to each other.

12. A magnetically actuated reed switch assembly as in claim 11 and wherein:

a. said reeds are polarized in a direction such that their respective magnetic fields aid each other and are normally closed.

13. A magnetically actuated reed switch assembly as in claim 12 and wherein:

a. said reeds are transverse to each other.

14. A magnetically actuated reed switch assembly as in claim 1 and wherein:

a. said reeds are flexible and b. said second reed is permanently polarized.

15. A magnetically actuated reed switch assembly as in claim 14 and wherein:

a. said reeds are transverse to each other.

16. A magnetically actuated reed switch assembly as in claim 14 and wherein:

a. said first reed is permanently polarized.

17. A magnetically actuated reed switch assembly as,

18. A magnetically actuated reed switch assembly as in claim 17 and wherein:

a. said reeds are transverse to each other.

19. A magnetically actuated reed switch assembly as in claim 23 and wherein: in claim 16 and wherein: a. said reeds are transverse to each other.

a. said reeds are polarized in a direction such that 25. A magnetically actuated reed switch assembly as their respective magnetic fields aid each other and in claim 1 and wherein: are norm ally open. a. said reeds are transverse to each other. 20. A magnetically actuated reed switch assembly as 26. A magnetically actuated reed switch assembly as in claim 19 and wherein: in claim 1 and wherein:

a. said reeds are transverse to each other, a. each of said reeds has a first portion and a second 21. A magnetically actuated reed switch assembly as p n t ans e se to said first portion. in laim 1 nd herei 27. A magnetically actuated reed switch assembly as a. said first reed is rigid and permanently polarized, in Claim 26 and in:

and a. said second portions cooperate with each other to b. said second reed is flexible form a Contact P id reeds are ll open, 28. A magnetically actuated reed switch assembly as 22. A magnetically actuated reed switch assembly as claim 27 and wherein! in claim 21 and wherein; a. each of said first portions are longer than each of a. said reeds are transverse to each other. secondPomonsl respectively 23. A magnetically actuated reed switch assembly as A magrletlcany actuated reed Switch assembly as in claim 1 and wherein; ll'l claim 1 and wherein:

said feeds are flexible a. one of said reeds is notched, and said fi t reed is permanently polarized b. the other oi" said reeds has a portion thereof c. said reeds are normally closed. dlsposed w'thm 531d notch- 24. A magnetically actuated reed switch assembly as 

1. A magnetically actuated reed switch assembly comprising: a. contact means including first and second cooperating magnetically actuated reeds in spaced relation to each other, b. a portion of said reeds being sealed in capsule means forming a substantially V-shaped bent configuration, said contacts cooperating with each other for making electrical contact at the apex of said ''''V'''' and c. magnetic means exerting a variable force field at the apex of said ''''V,'''' d. said magnetic means being sealed in said capsule means, e. said capsule means being gas impermeable.
 1. A magnetically actuated reed switch assembly comprising: a. contact means including first and second cooperating magnetically actuated reeds in spaced relation to each other, b. a portion of said reeds being sealed in capsule means forming a substantially V-shaped bent configuration, said contacts cooperating with each other for making electrical contact at the apex of said ''''V'''' and c. magnetic means exerting a variable force field at the apex of said ''''V,'''' d. said magnetic means being sealed in said capsule means, e. said capsule means being gas impermeable.
 2. A magnetically actuated reed switch assembly as in claim 1 and wherein: a. said magnetic means includes a rotatable magnet.
 3. A magnetically actuated reed switch assembly as in claim 2 and including: a. means for rotating said magnet.
 4. A magnetically actuated reed switch assembly as in claim 3 and wherein: a. said rotating means includes a motor.
 5. A magnetically actuated reed switch assembly as in claim 3 and wherein: a. said rotating means are manual.
 6. A magnetically actuated reed switch assembly as in claim 1 and wherein: a. said first reed is rigid and said second reed is flexible and permanently polarized.
 7. A magnetically actuated reed switch assembly as in claim 6 and wherein: a. said reeds are normally open and b. said second reed is polarized c. whereby said second reed will move into contact with said first reed once per revolution of said magnet when the opposing field of said magnet is sufficient to overcome the inherent resiliency of said second reed.
 8. A magnetically actuated reed switch assembly as in claim 7 and wherein: a. said reeds are transverse to each other.
 9. A magnetically actuated reed switch assembly as in claim 6 and wherein: a. said first reed is permanently polarized.
 10. A magnetically actuated reed switch assembly as in claim 9 and wherein: a. said reeds are polarized in a direction such that their respective magnet fields oppose each other and are normally open.
 11. A magnetically actuated reed switch assembly as in claim 10 and wherein: a. said reeds are transverse to each other.
 12. A magnetically actuated reed switch assembly as in claim 11 and wherein: a. said reeds are polarized in a direction such that their respective magnetic fields aid each other and are normally closed.
 13. A magnetically actuated reed switch assembly as in claim 12 and wherein: a. said reeds are transverse to each other.
 14. A magnetically actuated reed switch assembly as in claim 1 and wherein: a. said reeds are flexible and b. said second reed is permanently polarized.
 15. A magnetically actuated reed switch assembly as in claim 14 and wherein: a. said reeds are transverse to each other.
 16. A magnetically actuated reed switch assembly as in claim 14 and wherein: a. said first reed is permanently polarized.
 17. A magnetically actuated reed switch assembly as in claim 16 and wherein: a. said reeds are polarized in a direction such that their respective magnetic fields oppose each other and are normally open.
 18. A magnetically actuated reed switch assembly as in claim 17 and wherein: a. said reeds are transverse to each other.
 19. A magnetically actuated reed switch assembly as in claim 16 and wherein: a. said reeds are polarized in a direction such that their respective magnetic fields aid each other and are normally open.
 20. A magnetically actuated reed switch assembly as in claim 19 and wherein: a. said reeds are transverse to each other.
 21. A magnetically actuated reed switch assembly as in claim 1 and wherein: a. said first reed is rigid and permanently polarized, and b. said second reed is flexible c. said reeds are normally open.
 22. A magnetically actuated reed switch assembly as in claim 21 and wherein: a. said reeds are transverse to each other.
 23. A magnetically actuated reed switch assembly as in claim 1 and wherein: a. said reeds are flexible b. said first reed is permanently polarized c. said reeds are normally closed.
 24. A magnetically actuated reed switch Assembly as in claim 23 and wherein: a. said reeds are transverse to each other.
 25. A magnetically actuated reed switch assembly as in claim 1 and wherein: a. said reeds are transverse to each other.
 26. A magnetically actuated reed switch assembly as in claim 1 and wherein: a. each of said reeds has a first portion and a second portion transverse to said first portion.
 27. A magnetically actuated reed switch assembly as in claim 26 and wherein: a. said second portions cooperate with each other to form a contact pair.
 28. A magnetically actuated reed switch assembly as in claim 27 and wherein: a. each of said first portions are longer than each of said second portions, respectively. 